Background: Viburnum (Adoxaceae) is a species-rich woody genus whose taxonomy is complicated by morphological convergence and hybridization. Methods: We assembled complete plastomes of eight species representing five sections and analyzed their structural variation, sequence divergence, and molecular evolution. Results: All plastomes displayed the conserved quadripartite structure typical of angiosperms, with limited size variation attributable primarily to intergenic spacer-length polymorphisms. Sequence divergence was unevenly distributed, with single-copy regions exhibiting substantially higher nucleotide diversity than inverted repeat regions. We identified multiple hypervariable intergenic spacers such as the region trnK-UUU–rps16, suitable as molecular markers for population genetics and species identification. Selection pressure analysis revealed that while most protein-coding genes evolved under strong purifying selection, three genes involved in fatty acid biosynthesis and protein import—accD, ycf1, and ycf2—showed significantly relaxed constraints, suggesting ongoing functional divergence. Phylogenetic analysis recovered well-supported relationships consistent with previous classifications, while clarifying the positions of Viburnum amplificatum and Viburnum tinus. Conclusions: These findings provide molecular resources for Viburnum systematics and offer insights into the evolutionary dynamics of plastome genes with non-photosynthetic functions.

Background/Objectives: The elongated egg is a morphological mutant of silkworm (Bombyx mori) eggs, yet the biochemical processes and molecular mechanisms underlying this trait remain unclear. Methods: In this study, we performed transcriptome sequencing on the ovaries of female pupae from the Nistari silkworm strain (comparing normal and elongated eggs) during the first three days post-pupation using high-throughput sequencing. Results: A total of 153.56 Gb of filtered data was obtained, identifying 23,366 genes and 35,798 mRNAs. Comparative analysis across three control groups revealed 374 differentially expressed genes (DEGs), with 131 upregulated and 243 downregulated genes in the elongated egg group. Gene Ontology (GO) and the Kyoto Encyclopedia of Genes and Genomes (KEGG) enrichment analyses indicated that these DEGs were primarily associated with protein hydrolysis, DNA metabolic processes, and euchromatin/heterochromatin organization. Trend expression analysis revealed that transcriptional activity in elongated eggs was significantly higher than in normal eggs, particularly on day 3 of the pupal stage. Conclusions: Weighted gene co-expression network analysis (WGCNA) classified gene expression patterns into twelve modules, with two modules showing specificity. Thirteen hub genes were identified, which are functionally linked to translation initiation, protein density regulation, post-translational modification, and protein turnover. These findings provide foundational insights into the molecular mechanisms driving the formation of the elongated egg in silkworms.

Background/Objectives. Oxidative stress is a key contributor to HIV-associated neurocognitive disorders (HANDs), yet the regional organization and functional engagement of the NRF2 antioxidant pathway in the human brain remain incompletely defined. This study aimed to characterize NRF2 pathway architecture, baseline brain expression, and disease-associated transcriptional and coexpression remodeling across HAND stages. Methods. The NRF2 signaling network was reconstructed using curated pathway data and protein–protein interaction analysis to identify central hub genes. Baseline expression in the normal human cortex was assessed using the Human Protein Atlas. Transcriptomic profiling of postmortem brain samples from individuals with HAND (GSE35864) was performed using differential expression, hierarchical clustering, and region-specific coexpression analyses across white matter, frontal cortex, and basal ganglia. Results. Low-to-medium baseline expression of NRF2-related genes was observed in the normal cortex. Bulk differential expression revealed minimal NRF2 pathway modulation in the frontal cortex and basal ganglia. On the other hand, white matter exhibited robust NRF2 transcriptional activation specifically in HIV encephalitis (HIVE). Coexpression analysis performed specifically within HAND samples revealed a highly coordinated transcriptional organization of the NRF2 signaling network across all analyzed brain regions. Conclusions. NRF2 signaling in HAND is preserved as a coordinated transcriptional network but is selectively activated in white matter during encephalitic disease, highlighting region- and cell-type-targeted therapeutic opportunities.

Background/Objectives: The Bedouins (nomads) and the Fellahin (farmers) of Jordan represent two distinct subpopulations, characterized by unique lifestyles, settlement patterns, and linguistic features. This study aims to estimate the frequency of 27 Y-STRs in these two Jordanian subpopulations, along with various forensic parameters and paternal lineage comparisons with neighboring populations. Methods: Twenty-seven Y-STRs were typed in two major Jordanian subpopulations: Bedouin nomads (n = 101) and Fellahin farmers (n = 98). The forensic and paternal genetic lineage parameters and Y-haplogroup predictions were estimated. In addition, we conducted multidimensional scaling (MDS) and centroid analyses based on the Fst distance matrix to compare the sampled communities with neighboring populations from the MENA region, East Africa, Southeast Europe, and South Asia. Results: The Y-haplogroup predictions revealed differences in the predicted lineage composition based on the Y-STR profiles. The predicted J1a2a1a2 haplogroup predominated among the Bedouins (74.3%), whereas the Fellahin displayed a more heterogeneous profile, with notable frequencies of J1 (40%) and J2 (17.3%). Furthermore, the Fellahin exhibited remarkable genetic diversity and significant gene flow, providing plausible evidence of kinship with neighboring Levantine and Arabian groups. In contrast, the Bedouins showed consistently lower diversity across multiple loci, indicating long-term tribal isolation and, therefore, the potential effects of genetic drift. The MDS and centroid analyses positioned the Fellahin among the genetically interconnected Middle Eastern populations, while the Bedouins were clustered with the Arabian Peninsula populations. Conclusions: Overall, the contrasting genetic signatures of the two Jordanian subpopulations reflect their settlement patterns and sociocultural practices. In addition, the Y-STR dataset generated in this study enhances the Jordanian forensic database and to extends our understanding of paternal lineage structures in the West Asian/Levantine region.

Background/Objectives: Primary metabolic diseases including mitochondrial encephalomyopathies (ME), glycolytic enzymopathies, and disorders of lipid and amino acid metabolism can manifest with severe neurological and neuromuscular symptoms. Conversely, it is increasingly appreciated that primary neurodegenerative diseases can have metabolic etiology and pathophysiology. Pharmacological treatments have limited benefit for these classes of diseases, but dietary therapy is increasingly recognized as a tool for bolstering metabolic processes that can ameliorate neurological symptoms. The ketogenic diet is the best-established example, having long been used as a therapy for epilepsy. Replenishing metabolic intermediates (anaplerosis) especially substrates of the citric acid cycle (CAC) is currently being explored, with ongoing clinical trials of simple metabolic intermediates such as oxaloacetate or NAD+ to treat neurodegenerative diseases. We have shown ketogenic and anaplerotic therapies to be effective in a Drosophila model of ME; however, the full therapeutic potential and role of the CAC in neuronal health is still not well understood. Methods: Here, we have used genetic, behavioral, and dietary approaches to elucidate critical links between the CAC and neurological function. Results: We have found that stimulating the CAC can improve and sustain neurological health in the face of severe metabolic disease, and that its functions include a previously unrecognized role in maintaining normal circadian rhythms, whose disruption is often an early indicator or complicating factor in neurological and neurodegenerative disease. We investigated the hypothesis that the production of GTP by the CAC may be an important mechanistic contributor to the role of the CAC in neurological health and disease, and may underlie its therapeutic potential. Conclusions: Overall, our findings expand our understanding of the role of the CAC in neurological health and disease, support its development as a therapeutic target, and provide a foundation for further studies investigating the intersection between neurological disease and metabolic function.

Background/Objectives: Non-invasive samples offer an attractive alternative to logistically challenging invasive approaches in wildlife genetic studies but often contain low-quality host DNA that limits downstream analyses. Here, we assessed the applicability of moulted Eurasian goshawk feathers as a DNA source for whole-genome re-sequencing. Methods: We analysed 75 moulted feathers collected opportunistically from breeding territories. Each feather was measured from tip to tip, and its condition was visually assessed. Whole-genome re-sequencing was performed with a target coverage of 13× using 150 bp paired-end reads. Results: Feathers yielded an average of 7.19 ± 10.93 ng/μL DNA. DNA yield was positively correlated with feather size and the presence of blood traces in the calamus. On average, feather samples performed well, producing 208.7 ± 59.82 million reads, of which 82.69 ± 27.15% aligned to the reference genome, resulting in 83.58 ± 19.02% of the genome being covered at least once. After quality filtering, 10.34 ± 3.11 million biallelic single-nucleotide variants remained, of which 457,745 were common variants (MAF > 0.05). Larger feathers in good condition, with higher DNA yields and blood traces in the calamus, tended to perform better throughout the re-sequencing workflow. Nevertheless, approximately 22.7% of samples failed due to high missing data or poor genotype quality. Conclusions: Performance varied substantially even among samples with similar characteristics, indicating that improved sample selection incorporating direct measures of host DNA quality may be beneficial. Despite these challenges, moulted feathers represent a readily available DNA source for genome-wide re-sequencing of medium- to large-sized raptor species.

Background: Obsessive–compulsive disorder (OCD) is a heterogeneous psychiatric condition with substantial heritability. Early genetic studies were often underpowered and produced limited reproducibility, but recent large-scale genomic and multi-omic approaches are beginning to elucidate the genetic architecture of OCD. Objectives: This review aims to synthesise current evidence from recent genomic and epigenomic studies on OCD and their implications for molecular pathways of pathogenesis, including endophenotypes. Methods: We reviewed peer-reviewed literature and preprints published in recent years, focusing on multiple genetic approaches, including genome-wide association studies (GWAS), whole exome sequencing (WES), whole genome sequencing (WGS), and methylome-wide association studies (MWAS). We then integrated the results with endophenotypic evidence at the biochemical, physiological, structural, functional, and executive/cognitive levels. Results: Recent large-scale genomic studies provide strong evidence of a highly polygenic contribution from common variants, while rare coding and structural variants also contribute measurably, with enriched signals in pathways relevant to neurodevelopment and, in some cohorts, early-onset presentations. Epigenomic studies have moved from scattered findings to more replicable methylation patterns, including loci influenced by nearby genetic variation and indications of sex-dependent effects. Although convergence at the single-gene level remains limited, cross-study and cross-omics signals increasingly point to biological domains involving synaptic organisation and plasticity, neurological development and chromatin regulation, immune/stress pathways, and cellular homeostasis. Conclusions: The biology of OCD risk is best represented by an integrative model combining polygenic load, contributions from rare variants, and regulatory (epigenetic) mechanisms that influence intermediate phenotypes at the circuit and cognitive levels. The current findings are not yet clinically applicable for individual diagnosis; however, they may inform future multidisciplinary research frameworks and, in the longer term, contribute to the development of more personalised approaches in OCD.

Tetralogy of Fallot (TOF) is the most common cyanotic congenital heart disease, classically characterized by right ventricular outflow tract obstruction, ventricular septal defect, overriding aorta, and right ventricular hypertrophy. Recent advances in molecular and genomic research indicate that TOF is part of a phenotypic continuum encompassing Trilogy, Tetralogy, and Pentalogy of Fallot, in which the variability of anatomical presentation reflects shared genetic and epigenetic mechanisms with highly variable penetrance and expressivity. Variants in NOTCH1, FLT4, KDR, GATA6, and TBX1 highlight key pathways in conotruncal development and endothelial–mesenchymal transition, yet these well-known genes explain only a fraction of the genetic landscape. Emerging studies have identified additional candidate genes and networks involved in cardiac morphogenesis, including transcriptional regulators, signaling mediators, chromatin-remodeling factors, and splicing-associated genes such as PUF60 and DVL3. Epigenetic mechanisms, including DNA methylation, histone modifications, and non-coding RNA expression, further modulate phenotypic expressivity and contribute to variability along the Trilogy–Tetralogy–Pentalogy spectrum. This review integrates current genomic and clinical evidence to provide a comprehensive overview of the molecular architecture of Fallot-type conotruncal malformations, emphasizing the interplay between genetic and epigenetic mechanisms, genotype–phenotype correlations, and implications for diagnosis, risk stratification, counseling, and personalized management in the era of precision cardiology.

Background/Objectives: The retromer protein complex is involved in various physiological processes, especially endosomal trafficking, and its dysregulation has been linked to Alzheimer’s disease and Parkinson’s disease, as well as VPS35 knockout (KO), causing early embryonic lethality. We aimed to investigate the cellular consequences of VPS35 deficiency. Methods: To investigate the effects of VPS35 loss, we used CRISPR/Cas9 to generate VPS35 KO human embryonic kidney 293 (HEK293) cells. We analyzed changes in retromer component expression, cell proliferation, apoptosis, and mitochondrial dynamics using Western blotting, terminal deoxynucleotidyl transferase dUTP nick end labeling (TUNEL) assay, and confocal microscopy. Results: VPS35 KO led to a significant reduction in cell proliferation and decreased expression of VPS29 and VPS26, both essential for retromer complex assembly. Consequently, retromer formation was impaired. Compared to control cells, KO cells exhibited elevated levels of cleaved caspase-3, poly(ADP-ribose) polymerase, cytochrome C, and p21, while the expression of Ki-67, CDK4, and cyclin D was reduced. Additionally, VPS35 deletion also promoted mitochondrial fragmentation, associated with increased expression of mitochondrial fission-related proteins. Finally, the rescue experiment using the human VPS35 gene confirmed that the recovery of VPS35 not only led to the recovery of the essential elements constituting the retromer but also the recovery of molecules related to the cell cycle, restoring cell death to a normal level. Conclusions: These findings suggest that VPS35 plays a critical role in cell growth and survival by modulating apoptosis, mitochondrial dynamics, and cell cycle progression.

Background/Objectives: Segmental duplications (SDs) are major drivers of genome evolution and structural variation in primates, particularly within acrocentric chromosomes, where rDNA arrays and duplicated sequences are densely clustered. However, the evolutionary dynamics of rDNA-linked SDs across great ape lineages have remained poorly characterized due to longstanding technical limitations in genome assembly. Here, we investigate the organization, copy number variation, and evolutionary conservation of acrocentric SDs in great apes by integrating fluorescence in situ hybridization (FISH) with comparative analyses of telomere-to-telomere (T2T) genome assemblies. Methods: Using eight human-derived fosmid probes targeting SD-enriched regions flanking rDNA arrays, we analyzed multiple individuals from chimpanzee, bonobo, gorilla, and both Bornean and Sumatran orangutans. Results: Our FISH analyses revealed extensive lineage-specific variation in SD copy number and chromosomal distribution, with pronounced heteromorphism in African great apes, particularly gorillas, and more conserved patterns in orangutans. Several SDs showed fixed duplications across species, while others exhibited high levels of polymorphism and individual-specific organization. Conclusions: Comparison with T2T assemblies confirmed consistent genomic localization for a subset of probes, whereas others displayed partial discordance, highlighting the persistent challenges in resolving highly repetitive and structurally dynamic regions even with state-of-the-art assemblies. Genome-wide analyses further revealed species-specific enrichment of SDs on rDNA-bearing chromosomes, with chimpanzees and bonobos showing higher proportions than gorillas, and contrasting patterns between the two orangutan species. Overall, our results demonstrate that rDNA-linked SDs represent highly dynamic genomic compartments that have undergone differential expansion and remodeling during great ape evolution. These regions contribute substantially to inter- and intra-species structural variation and provide a mechanistic substrate for lineage-specific genome evolution, underscoring the importance of integrating cytogenetic and T2T-based approaches to fully capture the complexity of duplicated genomic landscapes.